Method and relative circuit for incrementing, decrementing or two&#39;s complementing a bit string

ABSTRACT

A method for incrementing, decrementing or two&#39;s complementing a first string of bits includes generating an auxiliary string of bits as a function of the first string, and logically combining the auxiliary string with the first string to generate a corresponding output string. A least significant bit of the auxiliary string is independent from the bits of the first string, and any other bit of the auxiliary string. The method is particularly convenient for generating an overflow flag when the number to be output exceeds the representation interval. An overflow flag is generated by logically combining the most significant bits of the first and auxiliary strings.

FIELD OF THE INVENTION

[0001] The present invention relates to complementation devices used in microprocessors, and in particular, to a method and an associated circuit for incrementing, decrementing or two's complementing a bit string.

BACKGROUND OF THE INVENTION

[0002] Generally, a microprocessor includes an Arithmetic and Logic Unit (ALU) for performing the four arithmetic operations. In the ALU, every integer number X is represented in the form of a bit string using the so-called two's complement coding. Indicating with X_(k) a generic bit of a string of N bits representing the number X ∈ └−2^(N-1), 2^(N-1)−1 ┘ the integer number X is given by $\begin{matrix} {X = {{\sum\limits_{k = 0}^{N - 2}\quad {X_{k} \cdot 2^{k}}} - {X_{N - 1} \cdot 2^{N - 1}}}} & (1) \end{matrix}$

[0003] This coding is very convenient because it allows the difference operation to be performed as a sum of relative numbers using a common adder.

[0004] The two's complement of a bit string X may be easily obtained by logic circuits. In fact, indicating with {overscore (X)} the one's complement of X is given by

{overscore (X)}=2^(N)−1−X   (2)

[0005] which is obtained by inverting each bit of the string X. The string Y_(TC)(X) representing the two's complement of X is simply obtained adding 1 to the one's complement of X is given by

Y _(RC)(X)={overscore (X)}+1=2^(N) −X   (3)

[0006] A two's complement circuit is depicted in FIG. 1. The two's complement circuit of the ALU may be used for performing increment or decrement operations. The circuit of FIG. 2 increments by one the string X because the string X+1 is the two's complement of the one's complement of the string X is given by

X+1={double overscore (X)}+1 =({double overscore (X)})+1 =Y _(TC)({overscore (X)})   (4)

[0007] Similarly, it is possible to demonstrate that the circuit of FIG. 3 decrements by one the string X, because the string X-1 is the one's complement of the two's complement of the string X is given by

X−1=2^(N)−2^(N) +X−1=2^(N)−1−(2^(N) −X)=2^(N)−1−Y _(TC)(X)={overscore (Y_(TC)(X))}  (5)

[0008] The fact that these increment and decrement operations can be performed by a two's complement circuit has lead to the realization of the so-called DIT (Decrement, Increment, Two's complement) circuits, such as the one depicted in FIG. 4. This circuit is substantially formed by a logic selection circuit SEL generating logic signals INV_IN and INV_OUT, by an array of input XOR gates input with the bits of the string X and the signal INV_IN, and by an array of XOR output gates receiving the bits of the two's complement string and the signal INV_OUT. The circuit of FIG. 4 performs a decrement, increment or two's complement operation, with the logic state of the commands ID and TC being determined according to the following table TABLE 1 ID TC OPERATION INV_IN INV_OUT 0 0 Decrement 0 1 1 0 Increment 1 0 — 1 two's 0 0

[0009] Because of the importance of the DIT circuit, the architecture thereof has been studied to find two's complement circuits that imply the smallest possible number of required elementary operations and that occupy the smallest possible silicon area. In the articles by R. Hashemian “Highly Parallel Increment/Decrement Using CMOS Technology”, Proceedings of the 33rd Midwest Symposium on Circuits and Systems, Calgari, Alberta, Canada, August 12-14, 1990 and by R. Hashemian and C. Chen “A New Parallel Technique For Design of Decrement/Increment and Two's Complement Circuits”, Proceedings of the 34th Midwest Symposium on Circuits and Systems, Monteray, Calif., May 14-17, 1991 techniques for forming decrement, increment and two's complement circuits are described, that offer certain advantages both in terms of silicon area consumption as well as in terms of speed.

[0010] By applying eq. 3, it is possible to note that the two's complement of the number −2^(N-1) is the number −2^(N-1) itself. This fact is due to the asymmetry of the interval X ∈ └−2^(N-1), 2^(N-1)−1┘, thus the two's complement of −2^(N-1) exceeds the representation interval.

[0011] In many applications the two's complement of −2^(N-1) is represented with the positive integer 2^(N-1)1

Y _(TC)(−2^(N-1))=2^(N-1)−1={overscore (X)}  (6)

[0012] generating at the same time an overflow flag OF signaling that the representation interval has been exceeded.

[0013] A known two's complement circuit with overflow check is depicted in FIG. 5. It generates an overflow flag OF when the string to be complemented represents the number −2^(N-1), and has a correction circuit CLIP that receives a two's complement string Z and the overflow flag OF, generating the correct output string Y.

[0014] The overflow check circuit OVERFLOW CHECK is input with the string X and with a string REF representing the number −2^(N-1), and activates the flag OF when the two strings coincide. The correction circuit CLIP generates an output string Y equal to the two's complement string Z when the flag OF is not active, while it produces the string 011 . . . 1 representing the number 2^(N-1)−1 when the flag OF is active. Unfortunately, the known two's complement circuit depicted in FIG. 5 is not convenient because the circuit OVERFLOW CHECK is an N bit comparator, whose silicon area occupation depends on the number of bits of the string X.

SUMMARY OF THE INVENTION

[0015] In view of the foregoing background, an object of the present invention is to provide a method and an associated circuit for incrementing, decrementing or two's complementing an N bit string X in a straightforward manner.

[0016] To perform these operations, the method of the invention generates an auxiliary string M of N bits as a function of the string X, and combines it logically with the string X to generate a corresponding output string Y. The least significant bit of the auxiliary string is independent from the bits of the string X, and any other bit M_(L) of the auxiliary string.

[0017] The operation of generating the auxiliary string M for performing the operations of increment, decrement and two's complement is particularly convenient for generating an overflow flag when the number to be output exceeds the representation interval. In fact, according to the method of the invention, an overflow flag OF is generated simply by combining logically the most significant bits M_(N-1) and X_(N-1) of the strings M and X. This is a great advantage because the overflow flag is generated by a single logic gate input with the bits M_(N-1) and X_(N-1), independently from the number of bits N of the string X, while in known two's complement circuits it is generated by an N bit comparator that occupies a silicon area that is non-negligible and depends on the length of the string X.

[0018] Obviously, depending on the fact that an increment, decrement or two's complement operation is to be performed, the strings X and M are combined according to different logic operations for generating the output string Y.

[0019] The method of the invention is implemented by a circuit for incrementing, decrementing or two's complementing a string formed by a number of N bits. The circuit comprises an auxiliary circuit generating an auxiliary string of N bits as a function of the first string. The least significant bit of the auxiliary string is independent from the first string and any other bit of the auxiliary string. The method starts from the second least significant bit up to the most significant bit, and performs a logic combination of a corresponding bit of the first string or of a negated replica thereof, starting from the least significant bit up to the second most significant bit, and of the bits of the first string or of the negated replica thereof less significant than the corresponding bit. Logic circuit means generate an output string as a logic combination of the auxiliary string and of the first string.

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] The different aspects and advantages of the present invention will appear even more evident through a detailed description of embodiments referring to the attached drawings, wherein:

[0021]FIG. 1 depicts a two's complement circuit of a string according to the prior art;

[0022]FIG. 2 depicts an increment circuit of a string using a two's complement circuit according to the prior art;

[0023]FIG. 3 depicts a decrement circuit of a string using a two's complement circuit according to the prior art;

[0024]FIG. 4 depicts a multifunction DIT circuit without overflow check according to the prior art;

[0025]FIG. 5 depicts a two's complement circuit with overflow check according to the prior art;

[0026]FIG. 6a depicts a two's complement circuit of the invention having an auxiliary circuit OR MASK;

[0027]FIG. 6b depicts a two's complement circuit of the invention having an auxiliary circuit AND MASK;

[0028]FIG. 7a is a detailed view of the auxiliary circuit depicted in FIG. 6a;

[0029]FIG. 7b is a detailed view of the auxiliary circuit depicted in FIG. 6b;

[0030]FIG. 8a is a detailed view of a second embodiment of the auxiliary circuit depicted in FIG. 6a;

[0031]FIG. 8b is a detailed view of a third embodiment of the auxiliary circuit of FIG. 6a;

[0032]FIG. 9a depicts a decrement circuit of the invention using the two's complement circuit of FIG. 6a;

[0033]FIGS. 9b and 9 c depict alternative embodiments of the decrement circuit of FIG. 9a;

[0034]FIG. 10a depicts an increment circuit of the invention that uses the two'complement circuit of FIG. 6a;

[0035]FIGS. 10b and 10 c depict alternative embodiments of the increment circuit of FIG. 10a;

[0036]FIG. 11a depicts an increment/decrement circuit of the invention that uses the circuit of FIG. 6a;

[0037]FIGS. 11b, 11 c and 11 d depict alternative embodiments of the increment/decrement circuit of FIG. 11a;

[0038]FIG. 12a depicts a multifunction DIT circuit of the invention that uses the circuit of FIG. 6a;

[0039]FIGS. 12b and 12 c depict alternative embodiments of the multifunction DIT circuit of FIG. 12a;

[0040]FIG. 13 depicts a two's complement circuit of the invention with overflow test that uses the two's complement circuit of FIG. 6a;

[0041]FIG. 14 is a detailed view of the circuit of FIG. 13;

[0042]FIG. 15 depicts a multifunction DIT circuit of the invention with overflow check that uses the two's complement circuit of FIG. 6a;

[0043]FIG. 16 shows the functioning characteristics of a DIT circuit of the invention;

[0044]FIG. 17 depicts a circuit for decrementing or two's complementing with overflow check that uses the two's complement circuit of FIG. 6a, and has a correction circuit CLIP upstream the output array of XOR logic gates;

[0045]FIG. 18 illustrates another multifunction DIT circuit of the invention with overflow check that uses the circuit of FIG. 17;

[0046]FIG. 19 depicts in detail an embodiment of the multifunction DIT circuit of FIG. 18; and

[0047]FIG. 20 depicts in detail another embodiment of the multifunction DIT circuit of FIG. 18.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0048] Two equivalent embodiments of two's complement circuits implementing the method of the invention are depicted in FIGS. 6a and 6 b. They have an auxiliary circuit OR MASK and AND MASK, respectively, input with the N-1 least significant bits of the string X and generating a corresponding auxiliary string M and {overscore (M)} of N bits.

[0049] It is worth noting that the auxiliary string {overscore (M)} generated by the circuit AND MASK is a negated version of the string M generated by the circuit OR MASK. The two circuits of FIGS. 6a and 6b are thus nearly equivalent.

[0050] According to the method of the invention, with X_(L-1) being the least significant bit X of the string X equal to 1, the least significant bits of the auxiliary string from the second M₁ to the (L+l)-th M_(L) generated by the circuit of FIG. 6a (or 6 b) coincide with the L least significant bits of the string X (or with their negated replicas), while the remaining bits are all equal to 1 (or to 0), while the least significant bit of the auxiliary string M is independent from the string X and is 0 (or 1).

[0051] The circuit of FIG. 6a effectively performs the two's complement of the string X. From simple calculations one finds that the two's complement (eq. 3) of the string X is the logic XOR between the string X and the string M

Y _(TC)(X)=X ⊕ M   (7)

[0052] An auxiliary circuit OR MASK that is easy to form is shown in FIG. 7a. It is substantially composed of an array of OR gates in cascade, with each gate being input with a bit of the string X and with the output of the OR gate that precedes in the cascade.

[0053] An auxiliary circuit AND MASK for the two's complement circuit of FIG. 6b is depicted in FIG. 7b. It is substantially similar to the circuit of FIG. 7a but it has AND gates instead of OR gates and generates an auxiliary string {overscore (M)} which is the negated replica of the auxiliary string M generated by the circuit of FIG. 7a.

[0054] As will be evident to those skilled in the art, it is possible to form the circuits of FIGS. 7a and 7 b even using NOR and NAND gates instead of OR and AND gates.

[0055] The auxiliary circuit OR MASK (AND MASK) is substantially a circuit that generates a string M whose L least significant bits are equal to 0(1) and all the remaining bits are equal to 1 (0), with X_(L-1) being the least significant bit equal to 1 of the string X. Therefore, it is evident that the auxiliary circuit of FIG. 7a (7 b) may be substituted by any other circuit that carries out the same operation. For example, it is possible to substitute the circuit of FIG. 7a, which has OR gates in series, with auxiliary circuits OR MASK of FIG. 8a and 8 b, that have OR gates disposed in parallel and in a hybrid series-parallel structure, respectively. Alternative structures, similar to those of FIGS. 8a and 8 b, may also be simply realized for the auxiliary circuit AND MASK of FIG. 7b.

[0056] For better illustrating the invention, in the ensuing description reference will be made to the embodiment of FIG. 6a with the auxiliary circuit OR MASK of FIG. 7a, but what will be stated can be easily repeated even for the embodiment of FIG. 6b and for all other embodiments of the auxiliary circuit.

[0057] The two's complement circuit of the invention may be used for forming a circuit for decrementing, depicted in FIG. 9a, a circuit for incrementing, depicted in FIG. 10a, an increment/decrement circuit depicted in FIG. 11a, or finally a multifunction DIT circuit, depicted in FIG. 12a. Alternative embodiments of decrement, increment, increment/decrement and multifunction DIT circuits equivalent to those of FIGS. 9a, 10 a, 11 a and 12 a are depicted in FIGS. 9b and 9 c, in FIGS. 10b and 10 c, in FIGS. from 11 b to 11 d and in FIGS. 12b and 12 c, respectively.

[0058] The truth table of signals ID, TC, INV_IN and INV_OUT is TABLE 1 and the logic selection circuit SEL of FIGS. from 12 a to 12 c is the same of FIG. 4.

[0059] The method of the invention allows the generation of the overflow flag simply as a logic combination only of the most significant bits M_(N-1) and X_(N-1) of the auxiliary string M and of the string to be complemented X, respectively, independently from the number N of bits of the string to be complemented. A two's complement circuit of the invention with overflow check is depicted in FIG. 13. The circuit OVERFLOW CHECK can generate the overflow flag OF only using the most significant bits X_(N-1) and M_(N-1) because when the string X represents the number −2^(N-1), and only in this case, the bit X_(N-1) is 1 and the bit M_(N-1) is 0.

[0060] A great advantage of the present invention with respect to the known two's complement circuit of FIG. 5 includes the fact that the overflow flag OF is generated independently from the number N of bits of the string X, and the circuit OVERFLOW CHECK occupies a silicon area smaller than the area of an N bit comparator.

[0061] A detailed scheme of an embodiment of a two's complement circuit of the invention that performs the correction of eq. 6 is depicted in FIG. 14. The XOR gate input with the bits X₀ and M₀ has been omitted because the least significant bit of the auxiliary string M₀ is always 0, and thus this gate is unnecessary.

[0062] Moreover the gate of the two's complement circuit input with the most significant bits M_(N-1) and X_(N-1) and generating the bit Z_(N-1) is an OR gate and not a XOR gate, in order to correct the output when the string X to be complemented represents the number −2^(N-1). In fact, independently from the state of the flag OF, the most significant bit Y_(N-1) of the output string may be generated by negating the bit Z_(N-1), as it is evident from the following table: TABLE 2 X M_(N−1) X_(N−1) Y_(N−1) Z_(N−1) 0 . . . 0 0 0 0 1 −2^(N−1) 0 1 0 1 any other 1 — {overscore (X_(N−1))} X_(N−1)

[0063] The two's complement circuit with overflow test of FIG. 13 may be used for realizing a multifunction DIT circuit of the invention for decrementing, incrementing and two's complementing, as depicted in FIG. 15, whose circuit blocks are the same as that of FIGS. 4 and 13. It is easy to demonstrate that the features that describe the functioning of the DIT circuit of FIG. 15 are that depicted in FIG. 16.

[0064]FIG. 17 depicts a general diagram of a preferred embodiment of a two's complement or decrement circuit of the invention. As it is possible to note, differently from the multifunction DIT circuit of FIG. 15, the correction circuit CLIP is upstream the array of output XOR gates and is not input with a bit string but only with two signals, INV_OUT and OF, whichever the number N of bits of the string K is.

[0065] The correction circuit CLIP generates a correction signal INVCLIP and a negated replica of the signal INV_OUT for making the array of output XOR gates perform the correction of eq. 6 of the complemented string Z. Therefore, the array of output XOR gates of the two's complement or decrement circuit of the invention is useful also when no decrement operation has been requested. This expedient allows a simplification of the structure of the correction circuit CLIP with a further saving of silicon area.

[0066] The two's complement or decrement circuit of the invention may be embodied in a multifunction DIT circuit for incrementing, decrementing or two's complementing a string as shown in FIG. 18. The truth table of signals INV_IN and INV_OUT is TABLE 1, already written referring to the multifunction DIT circuit of FIG. 4.

[0067] A detailed scheme of an embodiment of the multifunction DIT circuit of FIG. 18 is depicted in FIG. 19. In this embodiment, which is even more convenient than that of FIG. 15, the overflow flag OF is generated by ANDing the most significant bit of the string to be two's complemented K_(N-1) and a negated replica of the most significant bit of the auxiliary string M_(N-1), and the correction signal INVCLIP is the logic XOR between the overflow flag OF and the signal INV_OUT.

[0068] The circuit of FIG. 19 performs the same functions of that of FIG. 15. Should an overflow occur (OF=1), it would mean that the string K to be complemented represents the number —2^(N-1), and thus the most significant bit Z_(N-1) of the complemented string is 1 while all other bits are 0. In the case in which any decrement operation has been required (INV_OUT=0), the correction signal INVCLIP is 1 and thus the N-1 least significant bits of the output string Y are 1 while the most significant bit Y_(N-1) is 0. In the case in which a decrement operation has been required (INV_OUT=1), the correction signal INVCLIP is 0 and the output string Y is equal to the complemented string Z.

[0069] It is possible to verify immediately that, in all other possible cases, the operating characteristics of the DIT circuit of FIG. 19 are that depicted in FIG. 16. An embodiment of the invention, alternative to that of FIG. 19, is depicted in FIG. 20. The comprehension of its functioning is immediate and will not be described in detail. 

That which is claimed is:
 1. A method for incrementing, decrementing or two's complementing a N bit string (K), comprising generating an auxiliary string (M; {overscore (M)}) of N bits, in function of said string (K), whose least significant bit is independent from said string (K) and any other bit (M_(I); {overscore (M₁)}), starting from the second least significant bit (M₁; {overscore (M₁)}) up to the most significant bit (M_(N-1); {overscore (M_(N-1))}), is a logic combination of a corresponding bit (K_(I-1); {overscore (K₁₋₁)}) of said first string (K) or of a negated replica thereof ({overscore (K)}), starting from the least significant bit (K₀; {overscore (K₀)}) up to the second most significant bit (K_(N-2); {overscore (K_(N-2))}), and of the bits of said first string (K) or of the negated replica thereof ({overscore (K)}) less significant than said corresponding bit (K₀, . . . , K_(I-2); {overscore (K₀)}, . . . , {overscore (K₁₋₂)}) generating an output string (Y) as a logic combination of said auxiliary string (M; {overscore (M)}) and of said first string (K).
 2. The method of claim 1, wherein the least significant bit of said auxiliary string (M) is always null and any other bit (M_(I)), starting from the second least significant bit (M_(N-1)) up to the most significant bit (M_(N-1)), is the logic OR of a corresponding bit of said first string ({overscore (K₁₀₁)}) or of a negated replica thereof ({overscore (K₁₋₁)}) and of said bits less significant than said corresponding bit (K₀, . . . , K_(I-2); {overscore (K₀)}, . . . {overscore (K₁₋₂)}).
 3. The method of claim 1, wherein the least significant bit of said auxiliary string ({overscore (M)}) is always 1 and any other bit ({overscore (₁)}), starting from the second least significant bit ({overscore (₁)}) up to the most significant bit ({overscore (M_(N-1))}), is the logic AND of a corresponding bit of said first string (K_(I-1)) or of a negated replica thereof ({overscore (K₁₋₁)}) and of said bits less significant than said corresponding bit (K₀, . . . , K_(I-2); {overscore (K)}₀, . . . , {overscore (K₁₋₂)}).
 4. The method of claim 1, further comprising generating an overflow flag (OF) as a logic combination among the most significant bits of said auxiliary string (M_(N-1); {overscore (M_(N-1))}) and of said first string (K_(N-1)).
 5. The method of claim 2 for two's complementing said first string (K), wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said first string (K_(I-1)); said output string (Y) is obtained as XOR of said string (K) to be complemented and of said auxiliary string (M).
 6. The method of claim 3 for two's complementing said first string (K), wherein said other bit of the auxiliary string ({overscore (M₁)}) is obtained by ANDing the immediately less significant bit ({overscore (M₁₋₁)}) of said auxiliary string ({overscore (M)}) and a corresponding bit of said first string (K_(I-1)); said output string (Y) is obtained as negated XOR of said string (K) to be complemented and of said auxiliary string ({overscore (M)}).
 7. The method of claim 2 for decrementing said first string (K), wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said first string (K_(I-1)); said output string (Y) is obtained as negated XOR of said first string (K) and of said auxiliary string (M).
 8. The method of claim 3 for decrementing said first string (K), wherein said other bit of the auxiliary string ({overscore (M₁)}) is obtained by ANDing the immediately less significant bit ({overscore (M₁₋₁)}) of said auxiliary string ({overscore (M)}) and a corresponding bit of said first string (K_(I-1)); said output string (Y) is obtained as XOR of said first string (K) and of said auxiliary string ({overscore (M)}).
 9. The method of claim 2 for incrementing said first string (K), wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and the negated replica ({overscore (K₁₋₁)}) of a corresponding bit of said first string (K_(I-1)) said output string (Y) is obtained by XORing said auxiliary string (M) and a negated replica of said first string (K).
 10. The method of claim 3 for incrementing said first string (K), wherein said other bit of the auxiliary string ({overscore (M₁)}) is obtained by ANDing the immediately less significant bit ({overscore (M₁₋₁)}) of said auxiliary string ({overscore (M)}) and a corresponding bit of said first string (K_(I-1)); said output string (Y) is obtained as negated XOR of said first string (K) and of said auxiliary string ({overscore (M)}).
 11. The method of claims 2 and 4 for two's complementing or decrementing said first string (K), wherein said overflow flag (OF) is generated by ANDing the most significant bit of said first string (K_(N-1)) and a negated replica of the most significant bit of said auxiliary string (M_(N-1)).
 12. The method of claims 3 and 4 for two's complementing or decrementing said first string (K), wherein said overflow flag (OF) is generated by ANDing the most significant bit of said first string (K_(N-1)) and the most significant bit of said auxiliary string ({overscore (M_(N-1))}).
 13. The method of claims 2 and 4 for incrementing said first string (K), wherein said overflow flag (OF) is generated by ANDing the negated replicas of the most significant bits of said first string (K_(N-1)) and of said auxiliary string (M_(N-1)).
 14. The method of claims 3 and 4 for incrementing said first string (K), wherein said overflow flag (OF) is generated by ANDing the negated replica of the most significant bit of said first string (K_(N-1)) and the most significant bit of said auxiliary string ({overscore (M_(N-1))}).
 15. The method of claim 11 for two's complementing said first string (K) with correction of the output in case of overflow, wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); the most significant bit of said output string (Y) is obtained by NORing the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)), any other bit of said output string (Y) is obtained by ORing the overflow flag (OF) and the logic XOR between corresponding bits of said first string (K) and of said auxiliary string (M).
 16. The method of claim 11 for two's complementing said first string (K) with correction of the output in case of overflow, wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); the most significant bit of said output string (Y) is obtained by NORing the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)) any other bit of said output string (Y) is obtained by XORing the overflow flag (OF) and the logic XOR between corresponding bits of said first string (K) and of said auxiliary string (M).
 17. The method of claim 11 for decrementing said first string (K) with correction of the output in case of overflow, wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); the most significant bit of said output string (Y) is obtained by ORing the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)) ; any other bit of said output string (Y) is obtained by XORing the negated replica of the overflow flag (OF) and the logic XOR between corresponding bits of said first string (K) and of said auxiliary string (M).
 18. The method of claim 13 for incrementing said first string (K) with correction of the output in case of overflow, wherein said other bit of the auxiliary string (M_(I)) is obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and the negated replica ({overscore (K₁₋₁)}) of a corresponding bit of said string (K_(I-1)) ; the most significant bit of said output string (Y) is obtained by NORing the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)); any other bit of said output string (Y) is obtained by ORing the overflow flag (OF) and the logic XOR between corresponding bits of said first string (K) and of said auxiliary string (M).
 19. A circuit for incrementing, decrementing or two's complementing a N bit string (K), comprising an auxiliary circuit (OR MASK; AND MASK) generating an auxiliary string (M; {overscore (M₁)}) of N bits, in function of said string (K), whose least significant bit is independent from said string (K) and any other bit (M_(I); {overscore (M₁)}), starting from the second least significant bit (M₁; {overscore (M₁)}) up to the most significant bit (M_(N-1); M_(N-1)), is a logic combination of a corresponding bit (K_(I-1); {overscore (K₁₋₁)}) of said first string (K) or of a negated replica thereof ({overscore (K)}), starting from the least significant bit (K₀; {overscore (K₀)}) up to the second most significant bit (K_(N-2); {overscore (K_(N-2))}), and of the bits of said first string (K) or of the negated replica thereof ({overscore (K)}) less significant than said corresponding bit (K₀, . . . , K_(I-2); {overscore (K₀)}, . . . , {overscore (K₁₋₂)}); logic circuit means generating an output string (Y) as a logic combination of said auxiliary string (M; {overscore (M)}) and of said first string (K).
 20. The circuit of claim 19, wherein said auxiliary circuit (OR MASK) generates the auxiliary string (M) with the least significant bit always null, the second least significant bit of said auxiliary string (M) as replica of the least significant bit of the first string (K₀) or as negated replica thereof ({overscore (K₀)}), and further comprises N-2 OR gates each generating a respective bit of said auxiliary string (M), starting from the third least significant bit (M₂) up to the most significant bit (M_(N-1)) by ORing a corresponding bit (K_(I-1); {overscore (K₁₋₁)}) of said first string (K) or of a negated replica thereof ({overscore (K)}), starting from the least significant bit (K₀; {overscore (K₀)}) up to the second most significant bit (K_(N-2); {overscore (K_(N-2))}), and the bits of said first string (K) or of the negated replica thereof ({overscore (K)}) less significant than said corresponding bit (K₀, . . . , K_(I-2); {overscore (K₀)}, . . . , {overscore (K₁₋₂)}).
 21. The circuit of claim 19, wherein said auxiliary circuit (OR MASK) generates the auxiliary string (M) with the least significant bit always null, the second least significant bit of said auxiliary string (M) as replica of the least significant bit of the first string (K₀) or as negated replica thereof ({overscore (K₀)}), and further comprises N-2 OR gates each generating a respective bit of said auxiliary string (M), starting from the third least significant bit (M₂) up to the most significant bit (M_(N-1)), disposed in a cascade of pairs of logic gates, the gates of a first pair generating the third and fourth least significant bits of said auxiliary string (M₂, M₃) by ORing the two (K₀, K₁) and the three least significant bits (K₀, K₁, K₂), respectively, of said first string (K) or of the negated replica thereof ({overscore (K)}), each pair of OR gates being input with a respective pair of consecutive bits first (K_(I-2)) and second (K_(I-1)) of said first string (K) or of the negated replica thereof ({overscore (K)}) and the most significant bit of said auxiliary string generated by the pair of gates that precedes in the cascade (M_(I-2)), and generating two consecutive bits of said auxiliary string (M_(I-1), M_(I)) by ORing said most significant bit generated by the pair of gates that precedes in the cascade (M_(I-2)) and respectively said first bit (K_(I-2)) and both said bits first (K_(I-2)) and second (K_(I-1)) of said respective pair of bits.
 22. The circuit of claim 19, wherein said auxiliary circuit (OR MASK) generates the auxiliary string (M) with the least significant bit always null, the second least significant bit of said auxiliary string (M) as replica of the least significant bit of the first string (K₀) or as negated replica thereof ({overscore (K₀)}), and further comprises a cascade of N-2 OR gates input with a respective bit of said first string (K) or of the negated replica thereof in order starting from the second least significant bit (K₁) up to the second most significant bit (K_(N-2)), each gate generating a respective bit of said auxiliary string (M), starting from the third least significant bit (M₂) up to the most significant bit (M_(N-1)), as logic OR of the respective bit of said first string (K) or of the negated replica thereof and of the bit of the auxiliary string (M) generated by the OR gate that precedes in the cascade.
 23. The circuit of claim 19, wherein said auxiliary circuit (AND MASK) generates the auxiliary string ({overscore (M)}) with the least significant bit always equal to 1, the second least significant bit of said auxiliary string ({overscore (M)}) as replica of the least significant bit of the first string (K₀) or as negated replica thereof (K₀) and further comprises a cascade of N-2 AND gates input with a respective bit of said first string (K) or of the negated replica thereof in order starting from the second least significant bit (K₁) up to the second most significant bit (K_(N-2)), each gate generating a respective bit of said auxiliary string ({overscore (M)}), starting from the third least significant bit ({overscore (M₂)}) up to the most significant bit ({overscore (M_(N-1))}), by ANDing the respective bit of said first string (K) or of a negated replica thereof and the bit of the auxiliary string ({overscore (M)}) generated by the AND gate that precedes in the cascade.
 24. The circuit of claim 19, comprising an overflow control circuit (OVERFLOW CHECK) generating an overflow flag (OF) as logic combination among the most significant bits of said auxiliary string (M_(N-1); {overscore (M_(N-1))}) and of said first string (K_(N-1))
 25. The circuit of claim 22 for two's complementing said first string (K), wherein each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1),) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); said logic circuit means comprise an array of XOR gates, generating bits of said output string (Y) by XORing respective bits of said string to be complemented (K) and of said auxiliary string (M).
 26. The circuit of claim 22 for decrementing said first string (K), wherein each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); said logic circuit means comprise an array of XOR gates, generating bits of a two's complement string (Z) by XORing respective bits of said string to be complemented (K) and of said auxiliary string (M), and an array of NOT gates each input with a bit of the two's complement string and generating a corresponding bit of said output string (Y).
 27. The circuit of claim 22 for incrementing said first string (K), wherein each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and the negated replica ({overscore (K_(I-1))}) of a corresponding bit of said string (K_(I-1)); said logic circuit means comprise an array of XOR gates, generating bits of said output string (Y) by XORing respective bits of said string to be complemented (K) and of said auxiliary string (M).
 28. The circuit of claims 20 and 24 for two's complementing or decrementing said first string (K), wherein said overflow check circuit (OVERFLOW CHECK) is a logic AND gate generating said overflow flag (OF), input with the most significant bit of said first string (K_(N-1)) and a negated replica of the most significant bit of said auxiliary string (M_(N-1))
 29. The circuit of claims 23 and 24 for two's complementing or decrementing said first string (K), wherein said overflow check circuit (OVERFLOW CHECK) is a logic AND gate generating said overflow flag (OF), input with the most significant bits of said first string (K_(N-1)) and of said auxiliary string ({overscore (M_(N-1))}).
 30. The circuit of claims 20 and 24 for incrementing said first string (K), wherein said overflow check circuit (OVERFLOW CHECK) is a logic AND gate generating said overflow flag (OF), input with the negated replicas of the most significant bits of said first string (K_(N-1)) and of said auxiliary string (M_(N-1)).
 31. The circuit of claims 23 and 24 for incrementing said first string (K), wherein said overflow check circuit (OVERFLOW CHECK) is a logic AND gate generating said overflow flag (OF), input with a negated replica of the most significant bit of said first string (K_(N-1)) and the most significant bit of said auxiliary string ({overscore (M_(N-1))}).
 32. The circuit of claim 22 for incrementing or decrementing an input string (X) constituted by a number N of bits, comprising an input terminal for receiving a command signal (ID) of the operation to be performed; an array of N XOR gates each input with a respective bit of said input string (X) and with said command signal (ID) generating a corresponding bit of said first string (K); each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are generated by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); said circuit logic means comprising an array of logic gates generating bits of said output string (Y) by XORing a negated replica of said selection command (ID) and the logic XOR of respective bits of said input string (X) and of said auxiliary string (M).
 33. The circuit of claim 22, comprising a logic selection circuit (SEL) input with command signals (ID, TC) identifying the operation to be performed and generating a pair of selection signals first (INV_OUT) and second (INV_IN) whose logic state depends on the operation to be carried out, an array of N input XOR gates each input with a respective bit of said input string (X) and said second selection signal (INV_IN), generating said first bit string (K), each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); said logic circuit means comprising an array of logic gates generating bits of said output string (Y) by XORing said first selection signal (INV_OUT) and the logic XOR of respective bits of said input string (X) and of said auxiliary string (M).
 34. The circuit of claim 28 for two's complementing with correction of the output in case of overflow, wherein each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and a corresponding bit of said string (K_(I-1)); said logic circuit means comprise an OR gate input with the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)), generating the most significant bit of a two's complement string to be corrected (Z_(N-1)), an array of XOR gates generating the other bits of said two's complement string to be corrected (Z) by XORing corresponding bits of said first string (K) and of said auxiliary string (M); a correction circuit (CLIP) having p2 a NOT gate generating the most significant bit of said output string (Y_(N-1)) as negated replica of the most significant bit of said two's complement string to be corrected (Z_(N-1)), an array of N-1 OR gates generating respective other bits of said output string (Y), each gate being input with said overflow flag (OF) and with an output of a respective gate XOR of said array.
 35. The circuit of claim 28 for two's complementing or decrementing with correction of the output in case of overflow, having an input terminal receiving a selection signal (INV_OUT) of the operation to be performed, wherein each of said bits of the auxiliary string (M_(I)) starting from the third least significant bit (M₂) are obtained by ORing the immediately less significant bit (M_(I-1)) of said auxiliary string (M) and of a corresponding bit of said string (K_(I-1)); said logic circuit means comprise an OR gate input with the most significant bit of said first string (K_(N-1)) and the negated replica of the most significant bit of said auxiliary string (M_(N-1)), generating the most significant bit of a two's complement string to be corrected (Z_(N-1)), an array of XOR gates generating the other bits of said two's complement string to be corrected (Z) by XORing corresponding bits of said first string (K) and of said auxiliary string (M); an output logic circuit input with said two's complement string (Z), said overflow flag (OF) and said selection signal and said selection signal (INV_OUT), generating an output bit string (Y) equal to said two's complement string (Z) or obtained by negating all the bits thereof depending on the logic state of said selection signal (INV_OUT) and of said overflow flag (OF).
 36. The circuit of claim 35 for two's complementing or decrementing with correction of the output in case of overflow, wherein said output logic circuit comprises a logic correction circuit (CLIP) generating a negated replica of said selection signal ({overscore (INV_OUT)}) and a correction signal (INVCLIP) by XORing said selection signal (INV_OUT) and said overflow flag (OF); an array of N logic XOR gates, one of them being input with the most significant bit (Z_(N-1)) of said two's complement bit string (Z) and with said negated replica ({overscore (INV_OUT)}) generating the most significant bit of the output string (Y_(N-1)), and each other XOR gate being input with a respective other bit of said two's complement string (Z) and said correction signal (INVCLIP) generating corresponding other bits of the output string (Y).
 37. A multifunction circuit (DIT) for decrementing, incrementing or two's complementing an input N bit string (X), comprising a logic selection circuit (SEL) input with command signals (ID, TC) identifying the operation to be performed and generating a pair of selection signals first (INV_OUT) and second (INV_IN) whose logic state depends on the operation to be performed, an array of N XOR input gates each input with a respective bit of said input string (X) and with said first logic signal (INV_IN), generating said first bit string (K), a circuit for two's complementing or decrementing as defined in claim 35, input with said first bit string (K) and generating said output bit string (Y).
 38. The multifunction circuit (DIT) of claim 37, wherein said selection circuit (SEL) is input with a pair of command signals first (ID) and second (TC) and generates said first logic signal (INV_OUT) by NORing said command signals (ID, TC); said second logic signal (INV_IN) by ANDing said first command signal (ID) and a negated replica of said second command signal (TC). 